Figure 6.
Potential therapeutic targeting of ALCLs with MSCE116K. (A) Immunohistochemistry for MYC in 83 T-NHLs with and without MSCE116K, as indicated. Additional case details are given in supplemental Table 8. (B) Representative MYC expression in ALCLs with and without MSCE116K. (C) Karpas 299 cells expressing MSCE116K are more sensitive to JQ1 than are cells expressing MSCwt. Data represent relative fractions of GFP− cells in 0.2 μM JQ1 compared with vehicle for each of the constructs in competition with Karpas 299 cells overexpressing GFP. Summary of 3 independent experiments. (D) Treatment of Mac-1 cells stably expressing MSCwt or MSCE116K with JQ1 revealed increased sensitivity of MSCE116K to JQ1 compared with MSCwt (P = .004). (E) Model of interactions among MSC, E2F2, CD30, IRF4, and MYC in ALCL cells with MSCwt or MSCE116K. Briefly, MSCwt transcriptionally regulates E2F2 (Figure 4), and the resultant E2F2 protein represses expression of TNFRSF8 encoding CD30 (Figure 5). MSCE116K sequesters bHLH proteins but fails to bind to DNA, preventing heterodimer binding to canonical musculin and E2A target sequences (Figure 2) and inhibiting E2F2-mediated repression of CD30 (Figure 5). CD30 and IRF4 augment each other’s expression in a positive-feedback loop that leads to increased MYC expression and proliferation, as described previously.39 In addition, IRF4 transcriptionally regulates MSC to increase expression of MSCE116K, further augmenting expression of the CD30–IRF4–MYC axis (Figure 5). Although transcriptional regulation of MSC by IRF4 may also increase expression of MSCwt, this arrow is not indicated in the model because IRF4-MSCwt is not implicated in the same positive-feedback mechanism as IRF4-MSCE116K, MSCwt function is inhibited by the presence of dominant-negative MSCE116K, and MSCwt protein is less stable than MSCE116K and is present at lower levels. NS, not significant.